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1 SHORT DESCRIPTION OF THE BLACK SEA AND THE SEA OF AZOV The Black Sea and the Sea of Azov belong to the Atlantic Ocean basin. Waters of the Black Sea wash the shores of Ukraine, Russia, Georgia, Turkey, Bulgaria, and Rumania, and the Azov Sea waters - those of Ukraine and Russia. The seas are connected by the shallow Kerch Strait. They border along the line Cape Takyl – Cape Panagia. The Black Sea is connected with the Sea of Marmara by the Bosphorus Channel (the border is denoted by the line Cape Rumeli – Cape Anadolu) and farther through the Dardanelles - with the Mediterranean. The maximum length of the Black Sea (along 42º29'S) is 1148 km, its maximum width (between the town of Ochakiv and Cape Eregli) is 611 km, and its minimum width lies along the meridian of the southern point of the Crimea (Cape Sarych) and amounts 258 km. The maximum length of the Sea of Azov (between the Arabat Spit and the Don estuary) is 360 km and its maximum width is 176 km. The average depth of the Black Sea is 1300 m and maximum one is 2245 m. The Sea of Azov is shallow: its average depth is 7 m and maximum one is 15 m. The area of the Black Sea is about 423 thousand km, the volume of water in the sea is about 538 thousand km3. The area of the Sea of Azov is about 39 thousand km, the volume of the seawater is 290 thousand km3. The average level of the Black Sea is 7-11 cm lower than that of the Sea of Azov and 22 cm higher than that of the Sea of Marmara. The Black Sea belongs to the type of inland intercontinental oceanic seas, and the Sea of Azov is an inland shelf sea. The Black Sea bottom structure includes the regions with continental, subcontinental and subocean crust. In its topography shelf, continental slope, continental subslope and abyssal depression are distinctly observed. The shelf occupies about 25% of the sea bottom area. The shelf maximum width (200–250 km) is in the northwest; near the Southern Coast of the Crimea, the Caucasian and the Anatolian shores its width is several kilometers. Its surface slopes down very gradually in the direction of the abyssal depression at an angle of 0-1, somewhere reaching 2.5. The shelf is devided into interior (that may coincide with the underwater slope of the coastal zone), intermediate and exterior ones. The continental slope constitutes almost 40% of the bottom and is bounded by the isobaths of 100 and 2000 m. The depression bottom (below the isobath of 2000 m) makes almost 35% of the bottom area and represents an accumulation plain slightly inclined southward. The continental slope spreads as far as 1600-1900 m. It has a considerable gradient mainly about 11-13. The highest values are in limits 28-31° with maximum reaching 38°. The regions along the Southern coast of the Crimea (in particular, opposite the capes of Nikita, Massandra, Ayu-Dag) and along the Asia Minor coast (in particular, opposite the capes of 2 Perenit, Isikli, Demerliburun). The surface of continental slope is complicated with blocks of the earth's crust that often give it a graduated profile. The most part of the continental slope is complicated with underwater canyons of different origin. They can begin in the coastal zone at a depth of 10-15 m and reach 1600 m. The canyons are the most powerful means of transferring sedimentary material from the coast to the abyssal depression of the Black Sea. In the deepest part of the canyon the transferred sedimentary material forms big cones at a depth mainly 1600-1900 m. Individual cones can join that brings to formation of accumulative matter of the continental subslope. The mean rate of deposit accumulation at the bottom in the central part of the abyssal depression is usually 30-40 mm/1000 years. The predominantly flat bottom of the Sea of Azov descends gradually to the depression center. At the bottom there are a few positive forms of relief, the largest of them being the Pischana bank. The thickness of deposits, which cover the bottom of the Black sea, is dismembered on eleven material-genetic types. Six types are shallow and five - deep-water. Between all types of the deposits there are the continuous transfer conditioned by the gradual change of their grainsize and material composition. Terrigenous less calcareous aleuropelitic and pelitic silts prevail, on the second place are biogenic-terrigenous pelitic silts. Almost identically widespread biogenic much calcareous and sapropelic silts. There is the decline of content of terrigenous components in the youngest deposits and simultaneous growth of biogenic. In Holocene the dominant role of terrigenous sedimentation is common consistent pattern of formation of deep-water deposits of the Black sea, its importance being not the same for different parts of the basin (less in western, more in eastert part). In the regions of halystases of modern basin a biogenic factor is determining, the role of which in sediment accumulation increases from late Quarternary time, changing correlation of terrigenous and biogenic material in sediments. The length of the Black Sea coastline is 4725 km according to the measurements on the 1:100000 scale topographic map and 1629.1 km (34.5%) of them are located within Ukraine. In other countries it makes: 410 km (8.7%) in Russia, 315 km (6.7%) in Georgia, 1701 km (36.0%) in Turkey, 385 km (8.1%) in Bulgaria and 285 km (6.0%) in Romania. The total length of the Sea of Azov shores is 1860 km, 799 km of them being in Ukraine and the rest 1061 km in Russia The Black Sea coastline is slightly indented, only the low-lying shores of its northwestern part are cut by bays, inlets and estuaries. The northwestern coast of the Black Sea is low. To the east off the Sevastopol Bay the coast noticeably rises. The Kerch Peninsula shores are precipitous almost along the whole length except for the regions of barrier spits of limans and lagoons. The northeastern coast of the Black Sea is mainly high mountainous except for the 3 lowland area between the capes of Panagia and Anapa on the Taman’ coast. In the east the vast Colchis lowland approaches the sea. The southern coast of the sea is high and precipitous almost everywhere along the Nothern Taurus mountain system. It is interrupted with flat lowlands in the estuaries of large rivers such as Kizilirmak, Yesilirmak, Yenice, Sakarya. The coast west off the Bosphorus Strait is rather low and descends to lowland. The Strandjen and Mednorid high coasts begin from the Rezovo river estuary and reach the Burgas bay. Then there is a low coast as far as the Varna bay. The capes in this part drop steeply towards the sea. From the Cape Kaliakra to the great plain of the Danube delta the coast gradually descends. The shores of the Sea of Azov in the west, north and east are mainly low, whereas in the south they are steep. Like in the Black Sea, the existence of limans and lagoons is a characteristic feature especially in the north-west part. The second division with formation of large sand and shell spits as well as of barrier spits of different kinds is typical. They separate a number of shallow bays and limans from the sea. The largest of them, the Arabat Spit, separates the shallow Syvash Bay. At some high places there are active cliffs, the rate of abrasion is from 0.3 to 2.7 m/year in the north, from 0.2 to 4.2 m/year in the east, and <0.5 in the south. Accumulative forms develop under conditions of critical lack of deposits; they are subjected to current erosion sometimes being in dynamic equilibrium. Climatic conditions of the Black Sea and the Sea of Azov are determined by their geographical position and general atmospheric circulation. The northern part of the Black Sea and the Sea of Azov are located in the southern part of the moderate climate zone, and the southern part of the Black Sea - in the northern part of the subtropical climatic belt. In January mean air temperature above the central part of the Black Sea is 8ºC, in the northwestern part it decreases to 0–3ºC with the absolute minimum –30ºC. Mean air temperature in July is 22–24ºC with its maximum 35ºC. In the Sea of Azov cold winters (up to –33ºC) can be followed by dry and sultry summers (up to 40ºC). The annual amount of precipitations over the Sea of Azov and the west and northwest of the Black Sea is 300–500 mm, on the south of the Black Sea - 700– 800 mm, and on the east - 1800–2500 mm. Above the greater part of the Black Sea northerly and northeasterly winds prevail, whereas southerly and southeasterly ones are typical of its southeastern part. Average monthly wind speed is maximal in January–February (7–8 m/s) and minimal - in June–July (4–6 m/s). Constant maximum wind speed is observed in the western Black Sea, and the minimum one - in its southeast part. Ice is formed on the Sea of Azov every year. In severe winters it covers a considerable part and sometimes even the entire surface of the sea. In mild winters, ice is found in estuaries, bays, and along the coast. In the Black Sea ice that can hamper navigation is found only in the 4 northwestern part. Fast ice is formed annually only in the bays and estuaries. Complete freezing of the open areas in the northwestern part of the sea is possible only in very cold winters. A great number of rivers flow into the Black Sea. Their total runoff amounts up to 350 km3/yr. About 80% of the river runoff (Danube, Dnipro, Dnister, and Southern Buh) flows into the northwestern part of the sea. Total river runoff (Don and Kuban are the largest ones) into the Sea of Azov averages 35 km3/yr. In the coastal zone of the northern part of the Black Sea water temperature varies from the values of water freezing (–0.97ºC at the salinity 18‰ and –0.54ºC at the salinity 10‰) to 28– 29ºC under maximum warming-through. Mean water temperature in the Black Sea is about 9ºC. The thermal structure of the Black Sea is characterized by presence of cold intermediate layer, i.e. subsurface (40–80 m) layer of minimum temperature which is traditionally distinguished by the isotherm 8ºC. Below 75–100 m temperature monotonically increases with depth up to 9.1ºC on the bottom. Mean water temperature in the Sea of Azov is 11.5ºC. In winter on the sea surface in the regions of high salinity it decreases up to –1ºC (Syvash Bay), and in the low salinity regions - to –0.1ºC. In July and August water temperature in the major part of the sea is 24–25ºC (near the coast – up to 32ºC). Salinity of the Black Sea surface layer (18‰) is almost half as much as that of the ocean surface water, salinity in the Sea of Azov is even lower (10–12‰). Average salinity in the Black Sea increases monotonically from the surface (17.6‰ in May and 18.1‰ in February) to the bottom (22.33‰). The abyssal part of the sea receives highly saline water of the Sea of Marmara with the Lower Bosphorus current. The vertical haline structure is characterized by presence of two haloclines (the layers of salinity sudden change): the seasonal one – in the 0–30 m layer and the constant one – in the 50–200 m layer. The peculiarities of the thermohaline structure of the Black Sea water consist in a sudden change of density (conventional density reaches 16.15 – 16.25) called a main pycnocline. It results in a considerable restriction of the vertical water exchange. The water masses and the structure of the Black Sea water are formed as a result of interaction of the Sea of Marmara water mass brought by the Lower Bosphorus current and fresh water from rivers and precipitations. Five types of the Black Sea water masses are distinguished. They differ in their thermohaline characteristics: the coastal Black Sea water mass, the upper Black Sea water mass, the cold intermediate layer, the intermediate Black Sea water mass and the abyssal Black Sea water mass. The water mass of the Sea of Azov is formed by the water exchange with the Black Sea and by the fresh water inflow. In the Black Sea the cyclonic water motion prevails. It breaks up into two cyclonic circulations in the western and eastern parts of the sea in June - December. In the same period 5 under the decreased intensity of the general circulation of the sea, the anticyclonic eddies are developed localizing in the zone of the continental slope. The Sea of Azov currents are mainly caused by wind being of cyclonic character. The current structure in the Kerch Strait where the water flows can be directed from the Black Sea to the Sea of Azov and vice versa depending on the wind direction is the most complex. Under the prolonged winds the compensation currents directed against the wind occur in the strait. The Black Sea biogeochemical structure varies dramatically from the surface to bottom layers of water. There is a relatively thin upper oxic layer, where dissolved oxygen is abundant, and a thick deep anoxic layer, where oxygen is absent, while sulfide and other reduced sulfur species are plentiful. The overall redox budget and particularly the fluxes of oxygen and organic matter govern the possibility of sulfidic conditions. Oxidants are in lack in the Black Sea deep waters. The major reason for that is the presence of the permanent pycnocline that dramatically restricts the downward flux of oxygen, while the flux of sinking organic matter easily reaches the deepest layers and supports intensive anaerobic respiration of organic carbon. This produces and builds up the stock of sulfide. The biogeochemical structure of the layer above the permanent pycnocline and the processes that govern this structure are very similar to those in the major oxic part of the World Ocean. Oxygen is euphotically produced in the upper 30 to 40 meter layer of water or it is transported from the atmosphere. Physical exchange processes support the flux of oxygen from the upper to deeper layers of water. Oxygen reacts to organic matter. This results in consumption of oxygen, while organic carbon and nutrients are converted to their inorganic forms. The concentration of oxygen decreases, while the concentration of inorganic nutrients and the alkalinity increases with depth. The biogeochemical structure of the permanent pycnocline reveals dramatic redox transformations from oxic to anoxic conditions. The oxygen concentration decreases to 10 µM at the upper suboxic boundary, then oxygen expires near the sulfide onset. Changing redox conditions support nitrate to ammonium transition of inorganic nitrogen. The maximum of nitrate is traced above the upper suboxic boundary, and then the nitrate decreases with depth to completely expire near the sulfide onset. Ammonium starts to grow in the lower suboxic zone, where the peak of nitrite is traced. Varying redox conditions do not affect silica, and the concentration of silicate increases with depth. There is a local minimum of phosphate in the lower suboxic zone, and a local maximum of phosphate is traced in the upper anoxic zone. The biogeochemical structure below the permanent pycnocline reveals strengthening of anoxic conditions with depth. Oxygen is absent. Concentrations of sulfide, ammonium, silicate, and phosphate increase and reach their maxima in the bottom layer of water. 6 The process of formation of contemporary flora and fauna of the Black Sea has been going on for the last 5–8 thousand years after its recurrent joining with the World ocean. At present, according to their genesis, four main groups of hydrobionts are distinguished: Mediterranean immigrants, the most numerous in species and quantitative composition; Pontian autochthonous relicts; freshwater species; and the introduced species. According to the present notions, within the Ukrainian economic zone about 150 species of animal plankton have been discovered, among which there are several invading ones. At the same time some indigenous species have become extinct, including important foodstuff for fish larvae. According to the estimations of the 90ies, the content of ‘fodder’ zooplankton in the upper populated layer (150–200 m depth) varied from 1 to 25 g/m2. Sharp decrease of quantity and biomass of the ‘fodder’ zooplankton in the 90ies coincided with the invasion of the comb jellyfish (Mnemiopsis leidyi). Macrovegetation in the Ukrainian part of the Black Sea shelf numbers more than 270 species, including 4 species of seagrass and 2 species of flowers. In the algaflora red algae (almost 140 species) dominate, the amounts of brown and green algae are similar and half as much, respectively. Plant associations are common on the depth 020 m, but the largest thickets of macrophytes are concentrated within 15 m. During the last decades essential changes took place in composition and structure of Cystoseira and Phyllophora phytocenoses. They are most evident in the northwestern part of the Black Sea and in some places near the Crimean coast. Species composition, the amount of spawn and larvae, and larvae survival under different conditions are major indicators of the state of ichthyoplankton associations. In the early 90ies the amount of ichthyoplankton became by 1–2 orders of magnitude less in comparison with that in the 50ies–60ies, and the part of dead spawn increased from 40% to 80% and more. In 2000–2003 a part of dead spawn decreased approximately to 70%. The ichthyofauna of the Black Sea numbers almost 200 species and subspecies including stray fresh- and salt-water fishes known by single finds. Seawater fishes (about 140 species and subspecies) make up the major part of ichthyofauna and, in their turn, are classified into two groups: Mediterranean immigrants and boreal-Atlantic relicts. Mediterranean species inhabit mainly the upper warmed-through layer. More than 60 species of them have naturalized completely, even to the formation of endemic subspecies, and all the stages of their life cycle are connected with the Black Sea. Other species regularly migrate to feed from the other seas of the Mediterranean in the warm period of the year. The boreal-Atlantic subgroup is represented by 13 species which during the warm period of the year live mainly in the cold subsurface layer and get into the surface layer in winter. The group of brackish-water fishes numbers 22 endemic or 7 common with the Caspian Sea species and subspecies which are the autochthonous relicts of the brackish-water Lower Pliocene Pontian lake-sea. Anadromous and semi-migratory fishes are represented by 25 species that originated 1.5–2 mln years ago. The Far East mullet has been artificially acclimatized in the Azov-Black Sea basin. The Black Sea and the Sea of Azov are of great economic importance as a promising region of extraction of hydrocarbon resources, fishery zone, significant shipping lane, fishery zone, and possess a great recreation potential. Within the limits of the aquatorium there are known considerable mineral resources. Some deposits are industrially exploited. The deposits of hydrocarbon raw material are located within the limits of north-western shelf, perspective fields of gas hydrates are supposed in the region of deep water plain and continental slope. Ferrous, manganese and chromic ores gravitate to the off-shore area. Sites of distribution of ferrous-manganese concretions (perspective ores) are exposed on the shelf and in the upper part of continental slope along with the north, western and south coasts of the Black sea. The placer deposits of heavy metals and titanum-ilmenite located on a shelf in the tectonic area of Alpine orogenesis. Along the foot of continental slope of western part of the Black sea the sites of deposits enriched uranium are shown. Near the South Crimea coast, Caucasian shore and north-eastern seaboards of Turkey it is known submarine sources of fresh waters suitable for using. The deposits of building sand are intensively exploited. Mud volcanos are the pointers of modern active tectonic processes and searching signs for prospecting new mineral resources. Until recently, the Black Sea and the Sea of Azov were the most productive in the Mediterranean basin. However, the excessive level of anthropogenic impact in the last quarter of the 20th century resulted in a critical state of their ecosystems and a considerable decrease in fish capacity. In recent decades sprat and anchovy was the main food fish in the Azov-Black Sea basin. The Black Sea share in the total catch of these species in Ukraine exceeds 98%. In the Sea of Azov fishery is based on common kilka, anchovy, mullet, and zander, and now recovery of bullhead resources is observed. The present state of the resources of the most valuable species of the Azov-Black Sea basin – sturgeon, Black Sea salmon and turbot – causes anxiety. Izmail, Illichivs’k, Odesa, Yuzhne, Mykolaiv, Kherson, Sevastopol’, Feodosia, and Kerch are the largest Ukrainian ports on the Black Sea, and Berdians’k and Mariupol - on the Sea of Azov. Odesa, Illichivs’k, and Yuzhne are of special importance not only in the transportation system of Ukraine but also in the structure of international transportation corridors that are being developed actively. Favorable natural and climatic conditions open up vast opportunities for the development of resorts and tourism in the coastal zone of the both seas. The length of the seacoast in Ukraine 8 is about 2500 km and 1160 of them are valuable beaches. There are two major regions of natural recreation resources – the Crimean and the Azov-Black Sea ones. The Southern Coast of the Crimea is the largest climatic health resort. Sea curative mud deposits are a valuable element of the Ukrainian recreation potential. During recent decades, the ecosystems of the Black Sea and the Sea of Azov were subjected to heavy anthropogenic load. Among the crucial factors forming the major ecological problems are the influence of river runoff 80% of which inflow to the most ecologically vulnerable shallow northwestern part of the Black Sea, wastewater inflow from the point (especially dangerous for the Sea of Azov) and diffuse coastal sources, and pollutions from sea vessels. Eutrophication that affects the ecosystems of the Black Sea and the Sea of Azov is the most negative anthropogenic factor. The eutrophication level and the volume of entering pollutants exceeded the assimilation capacity of marine environment by early 80ies and over and over increased by middle 90ies. In 2000ies the ecological state rather improved: a stable tendency to restoration of bio-diversity and quantitative characteristics of numerous hydrobiont species including productive ones is observed; the degree of the basin eutrophication decreased but it did not reach the ecologically safe level.